Solar heater system for domestics waters

ABSTRACT

A solar heater with a primary circuit course in a panel for heating two separate inter connected storage reservoirs.

BACKGROUND OF THE INVENTION

There has always been a great interest in the use of solar power forheating water.

The systems of prior art, however, have a low yield and users thereforecomplain that they have to consume a large amount of back-up electricpower.

In order to resolve the problems existing in prior art, the applicanthas devised a high-yielding system which basically results from theassociation between panels, as well as a utilization of a highstratification reservoir (wherein the cold water that enters does notmix with the hot water that exits, and wherein only after the first 150litres are sufficiently hot are the other 150 litres heated).

Thus, a much higher yield is achieved, which provides much hotter waterwith the same solar radiation.

BRIEF DESCRIPTION OF THE DRAWINGS

The description which follows is based on the drawings attached hereto,which are of a non-restrictive nature and represent:

In FIG. 1, a panel belonging to prior art;

In FIG. 2, a panel according to the invention;

In FIG. 3, a perspective view and cross-section of the panel representedin FIG. 2.

PRIOR ART

Hereunder is a brief explanation of the mode of operation of the systemsof prior art, which function by thermosyphon, comparing them with thesystem of the invention (functioning by thermosyphon of panels connectedin series).

The primary circuit which functions by thermosyphon can have a volume,with this type of equipment, of around fifteen litres and it workssimply by gravity force and by the alteration of the water density dueto temperature variations (functioning by thermosyphon).

Thus, if there is solar radiation, the water in the primary circuit isconstantly travelling from panels (5) and (6) to reservoirs (3) and (4),where heat will be transferred from the water in the primary circuit tothe water for consumption by means of heat exchangers (9) and (10), andafterwards from reservoir to panels (5) and (6) to be heated again.

The said panels are constituted by tubes where the water from theprimary circuit circulates, by the sheet in the circuit which absorbsthe heat and joins the tubes in order to direct the heat to them, andalso by an insulating material and a piece of glass.

In the others systems of prior art, the water course in the primarycircuit is the following:

-   -   a) The less warm water which exits reservoir (C) goes down an        external tube in the panels, outside of the heating zone (A),        which causes loss of yield. The system of our invention does not        have this external tube.    -   b) In the other system which function by thermosyphon the panels        are arranged parallel to one other, i.e. upon each passage, the        thermofluid either passes through panel B or through panel B and        never through the two in the same cycle.    -   c) When the water enters the panels, and supposing that each        panel is two metres high and one metre wide, it will travel four        metres inside the heating zone (see FIG. 1), whatever its path        inside the tubes, and two metres outside subject to cooling.    -   d) When the water returns to the reservoir, it transfers all its        heat to just one reservoir (C), meaning that on days when there        is little solar radiation, it is difficult to raise the        temperature of the 300 litres of water, thus preventing it from        being used. However, in the system of the invention the first        150 litres of water are heated in the panels, and only after        they reach a very hot temperature are the other 150 litres        heated.    -   e) Since the solar heater systems of prior art have just one        reservoir, the cold water that enters mixes directly with the        hot water that exits, thereby producing right from the outset a        very unfavourable mix. In the system of the present invention,        by making use of the fact that the panels connected in series        function by thermosyphon, it is possible to obtain a drainage        speed suitable for transferring all the initial heat to the        first reservoir.

DETAILED DESCRIPTION OF THE INVENTION

As may be observed, the solar system of the invention for heatingdomestic water comprises solar panels functioning by thermosyphon inseries, which have a primary circuit containing a fluid that passesbetween heat exchangers (9 and 10) mounted on reservoirs (3 and 4)containing piped water to be heated and tubes (15, 25, 20 and 24) and(16, 26, 21 and 27) of the panels (6 and 5). The said fluid of theprimary circuit circulates by thermosyphon effect, the fluid of theprimary circuit that comes from heat exchanger (10) entering directlyinto panel (6) through tube (15) and being heated immediately eventhough it is flowing downwards.

In the system of the invention, the course of the primary circuit iscompletely different as the thermofluid (water and antifreeze) has totravel ten metres inside the panels and is therefore always subject toheating.

The main question is to determine how the water can travel downwardsafter it exits the reservoir, bearing in mind that when entering thepanels it will be heated and will want to travel upwards.

This is achieved by the fact that thermosyphon effect in the panels (6and 5) is possible due to the total closure (1-1′) of the upper tube(24), which forces the fluid to travel (18) down tube (15), even whileit is being heated, circulating to tube (25) and flowing up tubes (20)to tube (24), from which it passes to the adjacent panel (5), and due tothe partial closure (2-2′) of tube (27), which forces the fluid totravel (18) down tube (16), circulating to tube (26) and flowing up tube(21) to tube (27), the end of which is connected to heat exchanger (9)of reservoir (3).

The downwards path of the fluid of the primary circuit in vertical tubes(15 and 16) is guaranteed by the suction caused by the fluid flowing uptubes (20 and 21), due to the fact that these tubes are greater innumber than the single tube (15 and 16) in each of the panels.

Thus, for each panel of ten tubes, in nine tubes the water that wants totravel upwards will have sufficient power for there to be suction intube (15) where the water, even though it is being heated, will beforced to travel downwards.

Since there is no connection between panels (5) and (6) in the lowerpart, the water enters the second panel (5) from above (17) and in thesame way, in the first panel (6), the water is forced to travel down thefirst tube (16).

Therefore, the course of this primary circuit is metres long inside theheating zone, which is considerably greater than the four metres of theother systems.

This naturally means that the water in this primary circuit issignificantly warmer.

The partial closure (2-2′) has a bleeding function as it permits thepassage of air in order to allow the fluid to circulate and the panelsto be filled, i.e. if the primary circuit is filled through tube (7),the water will reach tube (25) and start to fill tubes (20), going downtube (16) and then filling tube (26), and when this happens the airremaining inside tubes (16, 20 and 24) will exit through the saidpartial closure (2-2′), thus avoiding air pockets which would preventthe thermosyphon from functioning, and if the primary circuit is filledthrough the other tube (8), the water will fill tubes (21, 16 and 26)and when it reaches tube (25), the air in tubes (20 and 24) will only beable to exit through the space reserved for the passage of air by meansof the said closure (2-2′), whereby it may be concluded that if theclosure (2-2′) were total, the thermosyphon would not function.

This passage of air and the passage of an insignificant amount of fluidof the primary circuit means that nearly all of the said fluid goes downtube (16), having for this purpose a small air passage which acts as ableeder for the system.

When entering the reservoirs, this circuit will have two heat exchangers(9) and (10) in the respective reservoirs (3) and (4). Thus, thethermofluid (water with antifreeze) which exits the panels and thenenters the left-hand reservoir (3) will start by heating the watertherein, and when the water passes to the second heat exchanger (10)(which is inside the right-hand reservoir (4)), it will already be muchlower in temperature (minimum temperature of the first reservoir). Thatis to say, for example, if the water reaches the first heat exchanger(9) at 80°, the temperature in the first reservoir can rapidly belowered to 50° in the upper part and 30° in the lower part.

Thus, the temperature which goes to the second heat exchanger (10) willbe approximately 30° and will not significantly heat up the secondreservoir.

As the temperature rises in the first reservoir which the water from theprimary circuit reaches (3), the transfer of heat from the secondreservoir (4) increases.

Thus, if we have water in the first reservoir in the upper part at 70°and in the lower part at 50°, the water from the primary circuit whichgoes to the second heat exchanger is already at a temperature of around50° and the water in the other reservoir starts to heat up totemperatures suitable for consumption.

This effect is achieved precisely by the fact that the two panelsfunction by thermosyphon and in series, which guarantees that thetemperature is much higher per cycle and that the speed of the cycle isthe most suitable for rapidly transferring the heat to the firstreservoir that it encounters.

The water for consumption which passes from the highest part of thereservoir on the right-hand side (4) to the left-hand side (3) is alsoforced to go down to the bottom (12) of the reservoir on the left-handside (3) for the same purpose, i.e. to delay as much as possible the“contact” between the piped water that enters (11) (which, throughoutits course, is progressively heated) and the water that exits (13).

The cold piped water which enters on the right-hand side (11), i.e. inthe reservoir containing water that is less hot (4), will not mixdirectly with the hot water that exits (13) the reservoir containinghotter water, thus preventing sudden decreases in the temperature of thewater for consumption.

As may be understood from the above, the course (22) of the fluid in theprimary circuit in the heat exchangers (9 e 10), in conjunction with thecourse (19) of the piped water to be heated in the reservoirs (3 e 4),allows the said reservoirs (3 e 4) to have a high degree ofstratification and function with different temperatures, in view of thefact that the greater the difference in temperature between the primaryfluid which reaches heat exchanger (9) from panel (5) and the pipedwater in reservoir (3), the greater will be the transfer of heatacquired in the panels (5 e 6) to the piped water in the said reservoir(3).

The cold piped water which enters reservoir (4) on the right-hand sidethrough tube (11) does not mix directly with the hot water which exitsthe top of reservoir (3) on the left-hand side through tube (13), whichallows the water to be progressively heated in the reservoir on theright-hand side (4), passing through tube (12) to the lower part of thereservoir on the left-hand side (3) so that it is heated even further inreservoir (3).

The tubes (7 e 8) for filling the primary circuit extend a fewcentimetres inside the respective heat exchangers (10 and 9), with theobjective of always having some air in the primary circuit in order toallow space for the increased volume of the fluid which occurs at hightemperatures, since the said circuit has to be plugged (23) so that thefluid will not evaporate when it reaches high temperatures.

1. Solar system for heating domestic water that comprises solar panelsfunctioning in series, which have a primary circuit containing a fluidthat passes between heat exchangers (9 and 10) mounted on tanks (3 and4) containing piped water to be heated and the tubes (15, 25, 20 and 24)and (16, 26, 21 and 27) of the panels (6 and 5), characterized in thatthe said fluid of the primary circuit circulates by thermosyphon effect,the fluid of the primary circuit that comes from the exchanger (10)entering directly into panel (6) through tube (15) and being heatedimmediately even though it is flowing downwards.
 2. Solar system forheating domestic water according to claim 1, characterized in that thethermosyphon effect in the panels (6 and 5) is achieved by the totalclosure (1-1′) of the upper tube (24), which forces the fluid to travel(18) down tube (15), while it is being heated, circulating to tube (25)and flowing up tubes (20) to tube (24), from which it passes to theadjacent panel (5), and due to the partial closure (2-2′) of tube (27),the fluid is forced to travel (18) down tube (16), circulating to tube(26) and flowing up tubes (21) to tube (27), the end of which isconnected to the exchanger (9) of tank (3).
 3. Solar system for heatingdomestic water according to claim 1, characterized in that the downwardspath of the fluid of the primary circuit in vertical tubes (15 and 16)is ensured by the suction caused by the fluid flowing up tubes (20 and21), due to the fact that the latter tubes are greater in number thanthe single tube (15 and 16) in each of the panels.
 4. Solar system forheating domestic water according to claim 1, characterized in that thepartial closure (2-2′) permits the passage of air in order to allow thefluid to circulate and the panels to be filled, i.e. if we fill theprimary circuit through tube (7), the water will reach tube (25) andstart to fill tubes (20), going down tube (16) and then filling tube(26), and when this happens the air remaining inside tubes (16, 20 and24) will exit through the said partial closure (2-2′), thus avoiding airpockets which would prevent the thermosyphon from functioning, and if wefill the primary circuit through the other tube (8), the water will filltubes (21, 16 and 26) and when it reaches tube (25), the air in tubes(20 and 24) will only be able to exit through the space reserved for thepassage of air by means of the said closure (2-2′), whereby it may beconcluded that if the closure (2-2′) were total, the thermosyphon wouldnot function.
 5. Solar system for heating domestic water according toclaim 4, characterized in that the partial closure (2-2′) permits thepassage of air and the passage of an insignificant amount of fluid ofthe primary circuit, meaning that nearly all of the said fluid goes downtube (16), having for this purpose a small air passage.
 6. Solar systemfor heating domestic water according to claim 1, characterized in thatthe passage (22) of the fluid in the primary circuit in the exchangers(9 and 10), in conjunction with the passage (19) of the piped water tobe heated in the tanks (3 and 4), allows the said tanks (3 and 4) to behighly stratified and to function at different temperatures, in view ofthe fact that the greater the difference in temperature between theprimary fluid that arrives at the heat exchanger (9) from the panel (5)and the piped water in tank (3), the greater the transfer of heatacquired in the panels (5 and 6) to the piped water in the said tank(3).
 7. Solar system for heating domestic water according to claim 6,characterized in that the cold piped water that enters tank (4) on theright-hand side through inlet tube (11) does not mix directly with thehot water that exits the top of tank (3) on the left-hand side throughinlet tube (13), which allows the water to be progressively heated inthe right-hand tank (4), passing through tube (12) to the lower part ofthe left-hand tank (3) to be heated further in tank (3).
 8. Solar systemfor heating domestic water according to claim 1, characterized in thattubes (7 and 8) for filling the primary circuit are placed a fewcentimetres inside the respective exchangers (10 and 9), with theobjective of always having some air in the primary circuit in order toallow room for the increase in volume of the fluid which occurs at hightemperatures, in view of the fact that the said circuit has to be closed(23) so that the fluid does not evaporate due to the high temperaturesthat it reaches.